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Laboratory #3
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In Today’s Lab
1) Bacterial growth curve2) MPN results3) Yeast fermentation4) Biofilm formation5) Gram stains
Bacterial Growth
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Bacterial Growth
• Increase in the number of cells• The bacterium reproduces by binary fission
– (12, 24….2n)• Growth measurements monitor changes in
the total number of cells or the mass of cells
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Binary Fission
• Asexual reproduction– DNA replication cellular elongation septum
formation septum completed and cell wall formation cellular separation and creation of daughter cells
• The quantity of all molecules doubles : proteins, DNA, RNA, lipids for membranes, cell wall materials, etc.
• Everything is distributes almost equally
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Growth Parameters
• Generation: 1 cell → 2 cells– The population doubles
• Generation time (g):– Time required for one cell division– g = time/n (n: number of generations)
• Growth rate (µ): – Change in cell number or mass/time
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Growth in batch Cultures
• CLOSED system– No addition of new nutrients– No elimination of waste products– Cells are not withdrawn
• Ex. Production of yogurt, beer fermentation, blood infection
• Cell density increases until something becomes limiting
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Growth Profile of Batch Cultures
9Time
Inoculation (Time= 0)
Log 1
0 of
cel
l num
ber
Lag Exponential Stationary Death
Lag or Adaptation Phase
• No increase in the number or the mass of cells• Active synthesis of components required for
growth in the given medium– Metabolic adaptation
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Exponential or Log Phase
• Development and cellular division occurs at maximum speed
• The number and mass of cells doubles at regular intervals
• The population is in physiological and biochemical equilibrium
• Division occurs at an exponential rate
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Exponential Division
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2nd doubling
3rd doubling
4th doubling
Final number of cells (N) = Initial number of cells (N0) X (2n)
n = number of doublings
1st doubling
Exponential Division
Time(h)
Number of generations (n)
Number of cells (N)
Time (h)
Number of generations (n)
Number of cells (N)
0 0 1 (20) 4.5 9 512 (29)
0.5 1 2 (21) 5 10 1024 (210)
1 2 4 (22) 5.5 11 2048 (211)
1.5 3 8 (23) 6 12 4096 (212)
2 4 16 (24) 6.5 13 8192 (213)
2.5 5 32 (25) 7 14 16384 (214)
3 6 64 (26) 7.5 15 32768 (215)
3.5 7 128 (27) 8 16 65536 (216)
4 8 256 (28) 8.5 17 131072 (217)
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Bacterial Growth Curve
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Growth Calculations
• If you start with one cell, how many will you have after 4 generations?– No= Initial number of cells– N = Number of cells after n generations– n = number of generation
• Formula : N= No(2n) • N = 1 (24) = 16 cell
• How many would you have if you started with 100 cells?
• How many would you after 5 generations if you started with 100 cells?
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Growth Calculations
• E. coli has a generation time of 20 minutes. If you start with 1 cell, how many will you have after 2 hours?– g=generation time and t=time– Formula: n=t/g– n=(2 hours x 60 minutes/hour)/20 minutes= 6
• N= No(2n)• N=1(26)=64 cells
• After 5 hours?
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Growth Calculations
Calculating Generation Time
• You start with 2 cells and end up with 2,000 cells after 2 h.– How many generations were there?– What is the generation time?
• Formula : n=3.3(logN-logNo)• Thus n=3.3(log (2000)– log (2)) = 9.9 generations• Formula : g=t/n• g=120 minutes/9.9 generations = 12.12 minutes/g
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Growth Rate - µ
• Growth as a function of time:– The shorter is the
generation time, the faster is the growth
– The faster is the growth, the steeper is the slope
– g=6 hours; slope 0.05
– g=2 hours; slope 0.15
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Population double en
6h
Pente: 0.05
Pente: 0.15
Population double en
2h
Time (h)
Calculating µ
• After 4 h of growth, an E.coli culture goes from 100 cells to 6.6 X 106 cells– What is the growth rate under these conditions?
• Formula: µ = ( (log10 N - log10 N0) 2.303) / (t - t0)• Thus µ = (log 6.6 X 106 – log 100) 2.303/ 4 = 2.8 cells/h
– What is the generation time? • Formula: µ = ln2/g or g = ln2/µ• Thus g = 0.69/2.8 = 0.25h or 15 minutes
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Growth rate Constant (K)
• K= Number of generations per unit time during exponential growth– Unit of time: h-1
• K= n/t– n = number of generations– t = number of hours
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Stationary Phase
• Arrest in cell growth• The population is no longer in equilibrium• Arrest due to a lack of nutrients, oxygen, or an
excessive accumulation of waste products, etc.• Represents the maximum yield under the given
conditions– Yg : Mass of microorganisms formed/mass (g) of
consumed substrate– Ym: Mass of microorganisms formed/mole of
consumed substrate21
Death Phase
• Exponential loss of viability due to a prolonged lack of nutrients or a prolonged exposure to waste products
• Not necessarily a loss in mass
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Biofilms
What are Biofilms?
• In nature over 90% of all bacteria live in biofilms
• Biofilms are collections of microorganisms that form on a hard surface
• Ex. The plaque that forms on teeth and the slime that forms on surfaces in watery areas
Problems Caused by Biofilms
• Tend to clog pipes and water filters• Can cause numerous diseases, including many
diseases prevalent in hospitals• Extra-resistance to antibiotics• Can form almost anywhere that water is
present, including catheters, kitchen counters, etc.
Formation of Biofilms
• Form in places with access to water• Attach to a solid surface using several means:
– Fimbriae– Hydrophobic Cell Walls– Sticky Polymers
Altruism Among Microorganisms
• Biofilms are like small cities• Have many very close neighbors that remain
together for extended periods of time• Biofilms encourage altruism• Bacteria will often sacrifice their maximum
growth rate in an effort to use the available community resources more efficiently
• While individuals are disadvantaged, community as a whole benefits
Fermentation by Yeast
Fermentation in Society
• The process of fermentation is critical for…– Fuel Ethanol Production– Bread making (yeast causes the bread to rise)– Alcoholic Beverages
What is Fermentation?
• Fermentation: a form of cellular energy metabolism done in an environment without oxygen (anaerobic)
• Yeast are frequently used as fermenters– They consume sugars for energy and release
byproducts such as ethanol and carbon dioxide• Industrial Fermentation is the process by
which ethanol is created from renewable plant materials
Fermentation Components
• Fermentation consists of…– Substrates – usually a sugar– Product – the substance created (ethanol)
• Fermentation requires an organism that can break down substrates in the absence of oxygen– Yeast (saccharomyces) is often the organism of
choice
Converting Glucose to Ethanol
• Summary:– Energy equivalents
• 2 ATP– Reducing equivalents
• 2 NADH– Three carbon compounds
• 2 pyruvates
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Each of these steps is carried out twice for each glucose molecule
Fermentation - Ethanolic
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• Organic electron acceptor- Acetaldehyde• Regeneration of NAD +